Your search keyword '"Thomas Schlechte"' showing total 12 results

1. A three-phase heuristic for the Fairness-Oriented Crew Rostering Problem

Author

Thomas Breugem, Thomas Schlechte, Christof Schulz, and Ralf Borndörfer

Subjects

General Computer Science, Modeling and Simulation, Management Science and Operations Research

Published

2023

2. Timetable optimization for a moving block system

Author

Thomas Schlechte, Ralf Borndörfer, Jonas Denißen, Simon Heller, Torsten Klug, Michael Küpper, Niels Lindner, Markus Reuther, Andreas Söhlke, and William Steadman

Subjects

Modeling and Simulation, Transportation, Management Science and Operations Research, Computer Science Applications, Civil and Structural Engineering

Published

2022

3. Conflict-free railway track assignment at depots

Author

Thomas Schlechte, Joseph Paat, Alexander Tesch, Rosemarie Martienssen, Brady Gilg, Senan Seymen, Torsten Klug, and Christof Schulz

Subjects

050210 logistics & transportation, Mathematical optimization, Engineering, 021103 operations research, business.industry, 05 social sciences, 0211 other engineering and technologies, Transportation, 02 engineering and technology, Management Science and Operations Research, Track (rail transport), Computer Science Applications, Shunting, FIFO and LIFO accounting, Modeling and Simulation, 0502 economics and business, Train, business, Assignment problem, Integer programming, Conflict free, Simulation, Civil and Structural Engineering

Abstract

Managing rolling stock with no passengers aboard is a critical component of railway operations. One aspect of managing rolling stock is to park the rolling stock on a given set of tracks at the end of a day or service. Depending on the parking assignment, shunting may be required in order for a parked train to depart or for an incoming train to park. Given a collection of tracks ℳ and a collection of trains T with a fixed arrival-departure timetable, the train assignment problem (TAP) is to determine the maximum number of trains from T that can be parked on ℳ according to the timetable and without the use of shunting. Hence, efficiently solving the TAP allows to quickly compute feasible parking schedules that do not require further shunting adjustments. In this paper, we show that the TAP is NP-hard and present two integer programming models for solving the TAP. We compare both models on a theoretical level. Moreover, to our knowledge, we consider the first approach that integrates track lengths along with the three most common types of parking tracks FIFO, LIFO and FREE tracks in a common model. Furthermore, to optimize against uncertainty in the arrival times of the trains we extend our models by stochastic and robust modeling techniques. We conclude by giving computational results for both models, observing that they perform well on real timetables.

Published

2018

4. Template-based re-optimization of rolling stock rotations

Author

Boris Grimm, Ralf Borndörfer, Thomas Schlechte, and Markus Reuther

Subjects

050210 logistics & transportation, Mathematical optimization, Engineering, 021103 operations research, business.industry, Mechanical Engineering, 05 social sciences, 0211 other engineering and technologies, Transportation, 02 engineering and technology, Management Science and Operations Research, Operational requirements, Template, 0502 economics and business, Template based, business, Stock (geology), Simulation, Information Systems, Re optimization

Abstract

Rolling stock, i.e., the set of railway vehicles, is among the most expensive and limited assets of a railway company and must be used efficiently. We consider in this paper the re-optimization problem to recover from unforeseen disruptions. We propose a template concept that allows to recover cost minimal rolling stock rotations from reference rotations under a large variety of operational requirements. To this end, connection templates as well as rotation templates are introduced and their application within a rolling stock rotation planning model is discussed. We present an implementation within the rolling stock rotation optimization framework rotor and computational results for scenarios provided by DB Fernverkehr AG, one of the leading railway operators in Europe.

Published

2017

5. Recent success stories on integrated optimization of railway systems

Author

Thomas Schlechte, Leonardo Lamorgese, Ralf Borndörfer, Markus Reuther, Carlo Mannino, and Torsten Klug

Subjects

050210 logistics & transportation, Engineering, Service quality, 021103 operations research, Operations research, Mathematical model, business.industry, 05 social sciences, Rail freight transport, 0211 other engineering and technologies, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Transportation, 02 engineering and technology, Management Science and Operations Research, Part iii, Planning process, Transport engineering, Capacity optimization, Discrete optimization problem, 0502 economics and business, Automotive Engineering, business, Implementation, Civil and Structural Engineering

Abstract

Planning and operating railway transportation systems is an extremely hard task due to the combinatorial complexity of the underlying discrete optimization problems, the technical intricacies, and the immense size of the problem instances. Because of that, however, mathematical models and optimization techniques can result in large gains for both railway customers and operators, e.g., in terms of cost reductions or service quality improvements. In the last years a large and growing group of researchers in the OR community have devoted their attention to this domain developing mathematical models and optimization approaches to tackle many of the relevant problems in the railway planning process. However, there is still a gap to bridge between theory and practice (e.g. Cacchiani et al., 2014; Borndorfer et al., 2010), with a few notable exceptions. In this paper we address three individual success stories, namely, long-term freight train routing (part I), mid-term rolling stock rotation planning (part II), and real-time train dispatching (part III). In each case, we describe real-life, successful implementations. We will discuss the individual problem setting, survey the optimization literature, and focus on particular aspects addressed by the mathematical models. We demonstrate on concrete applications how mathematical optimization can support railway planning and operations. This gives proof that mathematical optimization can support the planning of railway resources. Thus, mathematical models and optimization can lead to a greater efficiency of railway operations and will serve as a powerful and innovative tool to meet recent challenges of the railway industry.

Published

2017

6. Integrated Optimization of Rolling Stock Rotations for Intercity Railways

Author

Kerstin Waas, Markus Reuther, Steffen Weider, Thomas Schlechte, and Ralf Borndörfer

Subjects

050210 logistics & transportation, Engineering, Hypergraph, 021103 operations research, Cyclic scheduling, business.industry, 05 social sciences, 0211 other engineering and technologies, Transportation, 02 engineering and technology, Industrial engineering, Transport engineering, Trackage rights, 0502 economics and business, Programming paradigm, business, Integer programming, Stock (geology), Civil and Structural Engineering

Abstract

This paper proposes a highly integrated solution approach for rolling stock planning problems in the context of long distance passenger traffic between cities. The main contributions are a generic hypergraph-based mixed-integer programming model for the considered rolling stock rotation problem and an integrated algorithm for its solution. The newly developed algorithm is able to handle a large spectrum of industrial railway requirements, such as vehicle composition, maintenance constraints, infrastructure capacities, and regularity aspects. We show that our approach has the power to produce rolling stock rotations that can be implemented in practice. In this way, the rolling stock rotations at the largest German long distance operator Deutsche Bahn Fernverkehr AG could be optimized by an automated system utilizing advanced mathematical programming techniques.

Published

2016

7. The Freight Train Routing Problem for Congested Railway Networks with Mixed Traffic

Author

Hanno Schülldorf, Armin Fügenschuh, Torsten Klug, Thilo Schang, Thomas Schlechte, and Ralf Borndörfer

Subjects

050210 logistics & transportation, Static routing, Engineering, 021103 operations research, business.industry, 05 social sciences, Rail freight transport, 0211 other engineering and technologies, Transportation, Context (language use), 02 engineering and technology, Flow network, Transport engineering, Network element, Traffic congestion, 0502 economics and business, Train, Routing (electronic design automation), business, Civil and Structural Engineering, Computer network

Abstract

We consider the following freight train routing problem (FTRP). Given is a transportation network with fixed routes for passenger trains and a set of freight trains (requests), each defined by an origin and destination station pair. The objective is to calculate a feasible route for each freight train such that the sum of all expected delays and all running times is minimal. Previous research concentrated on microscopic train routings for junctions or inside major stations. Only recently approaches were developed to tackle larger corridors or even networks. We investigate the routing problem from a strategic perspective, calculating the routes in a macroscopic transportation network of Deutsche Bahn AG. In this context, macroscopic refers to an aggregation of complex and large real-world structures into fewer network elements. Moreover, the departure and arrival times of freight trains are approximated. The problem has a strategic character since it asks only for a coarse routing through the network without the precise timings. We provide a mixed-integer nonlinear programming (MINLP) formulation for the FTRP, which is a multicommodity flow model on a time-expanded graph with additional routing constraints. The model’s nonlinearities originate from an algebraic approximation of the delays of the trains on the arcs of the network by capacity restraint functions. The MINLP is reduced to a mixed-integer linear model (MILP) by piecewise linear approximation. The latter is solved by a state-of-the art MILP solver for various real-world test instances.

Published

2016

8. Multi-period line planning with resource transfers

Author

Ralf Borndörfer, Amin Ahmadi Digehsara, Güvenç Şahin, and Thomas Schlechte

Subjects

050210 logistics & transportation, Line planning, Operations research, business.industry, Computer science, 05 social sciences, Transportation, Time horizon, Variation (game tree), 010501 environmental sciences, 01 natural sciences, Computer Science Applications, Resource (project management), Public transport, Transfer (computing), 0502 economics and business, Automotive Engineering, Relevant cost, Line (text file), business, 0105 earth and related environmental sciences, Civil and Structural Engineering

Abstract

Urban transportation systems are subject to a high level of variation and fluctuation in demand over the day. When this variation and fluctuation are observed in both time and space, it is crucial to develop line plans that are responsive to demand. A multi-period line planning approach that considers a changing demand during the planning horizon is proposed. If such systems are also subject to limitations of resources, a dynamic transfer of resources from one line to another throughout the planning horizon should also be considered. A mathematical modelling framework is developed to solve the line planning problem with a cost-oriented approach considering transfer of resources during a finite length planning horizon of multiple periods. We use real-life public transportation network data for our computational results. We analyze whether or not multi-period solutions outperform single period solutions in terms of feasibility and relevant costs. The importance of demand variation on multi-period solutions is investigated. We evaluate the impact of resource transfer constraints on the effectiveness of solutions. We also study the effect of period lengths along with the problem parameters that are significant for and sensitive to the optimality of solutions.

Published

2020

9. On the Path Avoiding Forbidden Pairs Polytope

Author

Thomas Schlechte, Marco Blanco, Ralf Borndörfer, Nam-Dũng Hoang, and Michael Brückner

Subjects

Combinatorics, Discrete mathematics, TheoryofComputation_ANALYSISOFALGORITHMSANDPROBLEMCOMPLEXITY, Applied Mathematics, Shortest path problem, Discrete Mathematics and Combinatorics, Polytope, Special case, Directed acyclic graph, Graph, MathematicsofComputing_DISCRETEMATHEMATICS, Mathematics, Exponential function

Abstract

Given a directed, acyclic graph, a source and a sink node, and a set of forbidden pairs of arcs, the path avoiding forbidden pairs (PAFP) problem is to find a path that connects the source and sink nodes and contains at most one arc from each forbidden pair. The general version of the problem is NP-hard, but it becomes polynomially solvable for certain topological configurations of the pairs. We present the first polyhedral study of the PAFP problem. We introduce a new family of valid inequalities for the PAFP polytope and show that they are sufficient to provide a complete linear description in the special case where the forbidden pairs satisfy a disjointness property. Furthermore, we show that the number of facets of the PAFP polytope is exponential in the size of the graph, even for the case of a single forbidden pair.

Published

2015

10. Rapid branching

Author

Andreas Löbel, Thomas Schlechte, Markus Reuther, Ralf Borndörfer, and Steffen Weider

Subjects

Mathematical optimization, Optimization problem, Scale (ratio), Computer science, Heuristic (computer science), Mechanical Engineering, Node (networking), Transportation, Management Science and Operations Research, Crew scheduling, Key (cryptography), Column generation, Rotation (mathematics), Information Systems

Abstract

We propose rapid branching (RB) as a general branch-and-bound heuristic for solving large scale optimization problems in traffic and transport. The key idea is to combine a special branching rule and a greedy node selection strategy in order to produce solutions of controlled quality rapidly and efficiently. We report on three successful applications of the method for integrated vehicle and crew scheduling, railway track allocation, and railway vehicle rotation planning.

Published

2013

11. Micro–macro transformation of railway networks

Author

Thomas Graffagnino, Ralf Borndörfer, Elmar Swarat, Berkan Erol, and Thomas Schlechte

Subjects

Engineering, Decision support system, Schedule, business.industry, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Transportation, Management Science and Operations Research, Track (rail transport), Industrial engineering, Computer Science Applications, Capacity optimization, Modeling and Simulation, Headway, Train, Macro, business, Simulation, Civil and Structural Engineering, Network model

Abstract

This paper presents a bottom-up approach to automatic railway network simplification. Starting from a detailed microscopic level as it is used in railway simulation, the network is transformed by an algorithm to an aggregated level, i.e., to a macroscopic network, that is sufficient for long-term planning and optimization. Running and headway times are rounded to a user defined precision by a special cumulative method. After this “macrotization” trains from a given set of requests are added to the existing timetable by solving an optimal train path allocation problem. The objective of this problem is to maximize a sum of utilities of the allocated trains; the utility can be a constant, some monetary value, etc. The optimized schedule is re-transformed back to the microscopic level in such a way that it can be simulated without any conflicts between the train paths. We apply this algorithm to macrotize a microscopic network model of the highly frequented Simplon corridor in the Alps between Switzerland and Italy. To the best knowledge of the authors and confirmed by several railway practitioners this was the first time that track allocations that have been produced in a fully automatic way on a macroscopic scale fulfill the requirements of the originating microscopic model and withstand an evaluation in the microscopic simulation tool OpenTrack . Our micro–macro transformation method allows for a much faster planning and provides solutions of a quality that are at least comparable to the most sophisticated manual schedules. In this way meaningful scenario analyses can be carried out that pave the way towards a new level of decision support in railway planning.

Published

2011

12. Spectral estimation for long-term evolution transceivers using low-complex filter banks

Author

Thomas Schlechter, Christoph Juritsch, and Mario Huemer

Subjects

Long Term Evolution, radio transceivers, channel bank filters, telecommunication power management, telecommunication network reliability, radio spectrum management, spectral estimation, long-term evolution transceivers, mobile user equipments, power management, UE analogue, digital frontends, signal extraction, communication standards, communication reliability, environmental spectral conditions, generic spectrum sensing approach, AFE, DFE, low-complex multiplier free filter bank, spectrum sensing approach, chip area estimation, power consumption, CMOS technology database, Smarti4G chip, LTE networks, Engineering (General). Civil engineering (General), TA1-2040

Abstract

For mobile user equipments (UEs), a careful power management is essential. Despite this fact, quite an amount of energy is wasted in today's UEs’ analogue (AFEs) and digital frontends (DFEs). These are engineered for extracting the wanted signal from a spectral environment defined in the corresponding communication standards with their extremely tough requirements. These requirements define a worst-case scenario still ensuring reliable communication. In a typical receiving process the actual requirements can be considered as less critical. Knowledge about the actual environmental spectral conditions allows to reconfigure both frontends to the actual needs and to save energy. In this paper, the authors present a highly efficient generic spectrum sensing approach, which allows to collect information about the actual spectral environment of an UE. This information can be used to reconfigure both the AFE and DFE, thus endowing them with increased intelligence. A low-complex multiplier free filter bank extended by an efficient power calculation unit will be introduced. They also present simulation results, which illustrate the performance of the spectrum sensing approach and a complexity comparison with different well-known implementations is given. Furthermore, estimates on the chip area and power consumption based on a 65 nm CMOS technology database are provided, considering the Smarti4G chip as a reference.

Published

2014